biomolecular

简明释义

英[/ˌbaɪoʊˈmɒlɪkjʊlər/]美[/ˌbaɪoʊˈmɒlɪkjʊlər/]

生物分子的

英英释义

单词用法

同义词

反义词

例句

1.Due to the high parallelism and recognition ability of the biomolecules in biochemical reactions, biomolecular computing behaves great advantage in solving combinatorial optimization problems.

由于生物分子在化学反应中具有高度的并行性和识别能力，使生物分子计算在解决组合优化问题中显示出巨大的优势。

2.The network target treats a disease-specific biomolecular network as a target to help design and predict the best possible treatments.

网络靶标概念指的是将病证生物分子网络当作靶标，由此设计和预测最佳的药物干预方式。

3.In addition, the unique chemical, physical and biological properties of PNAs have been exploited to produce powerful biomolecular tools, antisense and antigene agents, molecular probes and biosensors.

此外，鉴于肽核酸独特的理化和生物学性能，人们正尝试将其用于生物分子工具、反义和反基因制剂、分子探针和生物传感器。

4.In this paper, a simple biomolecular pushdown automaton is constructed with a finite automaton and a pushdown store firstly, and an algorithm is designed to solve a kind of languages.

文中首先通过在分子有限自动机上扩展一个分子下推存储器从而获得了一种简单的分子下推自动机，并基于该下推自动机提出了一类语言的分子自动机解法。

5.This data bank stores the references of articles from the expanding field of mathematical and computer analysis of biomolecular sequences.

此数据库收录的参考文章来自生物大分子序列的数学和计算机分析这一扩展中的领域。

6.This paper presents a review of fundamental ideas, computing methods, applications and advances in biomolecular computing. Furthermore, the developmental trend of biomolecular computing is described.

本文总结了生物分子计算的基本思想与计算方法、生物分子计算的应用与进展，并对生物分子计算的发展趋势作了评述。

7.The technique of biomolecular interaction analysis (BIA) can observe real time biomolecular interactions.

生物大分子相互作用分析(BIA)技术可以实时观察分子间相互作用。

8.Understanding biomolecular structures can help in drug design.

理解生物分子结构有助于药物设计。

9.Scientists are exploring biomolecular pathways to develop targeted cancer treatments.

科学家正在探索生物分子途径，以开发针对性的癌症治疗。

10.The study of biomolecular interactions is crucial for understanding cellular processes.

研究生物分子相互作用对于理解细胞过程至关重要。

11.Recent advancements in biomolecular engineering have led to new therapies for diseases.

最近在生物分子工程方面的进展导致了新疗法的出现。

12.The lab specializes in biomolecular'>生物分子研究，重点关注蛋白质相互作用。

作文

The study of life at the molecular level has significantly advanced our understanding of biological processes. One key area that has emerged in recent years is the field of biomolecular (生物分子) research, which focuses on the interactions and functions of biological molecules. This discipline encompasses various aspects of molecular biology, biochemistry, and genetics, making it a multidisciplinary field that is crucial for scientific innovation.In biomolecular (生物分子) research, scientists investigate the structures and functions of proteins, nucleic acids, carbohydrates, and lipids. These biomolecules are essential for the structure and function of cells, and understanding their interactions is vital for deciphering the complexities of life. For instance, proteins play a critical role in catalyzing biochemical reactions, while nucleic acids are responsible for storing and transmitting genetic information.One of the most exciting developments in biomolecular (生物分子) science is the advent of techniques such as CRISPR-Cas9, which allows for precise editing of genes. This groundbreaking technology has opened new avenues for genetic engineering, with potential applications in medicine, agriculture, and biotechnology. By manipulating biomolecular (生物分子) structures, researchers can create organisms with desired traits, develop targeted therapies for diseases, and even address food security issues.Moreover, the integration of computational tools in biomolecular (生物分子) studies has revolutionized the way scientists approach complex biological questions. Bioinformatics, for instance, enables researchers to analyze vast amounts of data related to gene sequences, protein structures, and metabolic pathways. This synergy between experimental and computational methods has led to significant breakthroughs in our understanding of cellular processes and disease mechanisms.The importance of biomolecular (生物分子) research extends beyond academic inquiry; it has profound implications for public health and environmental sustainability. For example, understanding the biomolecular (生物分子) basis of diseases such as cancer or Alzheimer's can lead to the development of more effective treatments and preventive strategies. Additionally, studying the biomolecular (生物分子) interactions in ecosystems can provide insights into biodiversity conservation and the impacts of climate change.In conclusion, the field of biomolecular (生物分子) research is at the forefront of scientific discovery, bridging gaps between various disciplines and offering solutions to some of the most pressing challenges facing humanity. As we continue to explore the intricate world of biomolecules, we unlock the secrets of life itself, paving the way for innovations that can enhance our quality of life and protect our planet for future generations.